Robust ω-Transaminases by Computational Stabilization of the Subunit Interface

Qinglong Meng; Nikolas Capra; Cyntia M. Palacio; Elisa Lanfranchi; Marleen Otzen; Luc Z. Van Schie; Henriëtte J. Rozeboom; Andy Mark W.H. Thunnissen; Hein J. Wijma; Dick B. Janssen

doi:10.1021/acscatal.9b05223

Robust ω-Transaminases by Computational Stabilization of the Subunit Interface

Qinglong Meng, Nikolas Capra, Cyntia M. Palacio, Elisa Lanfranchi, Marleen Otzen, Luc Z. Van Schie, Henriëtte J. Rozeboom, Andy Mark W.H. Thunnissen, Hein J. Wijma, Dick B. Janssen

Research output: Contribution to journal › Article › peer-review

61 Scopus citations

Abstract

Transaminases are attractive catalysts for the production of enantiopure amines. However, the poor stability of these enzymes often limits their application in biocatalysis. Here, we used a framework for enzyme stability engineering by computational library design (FRESCO) to stabilize the homodimeric PLP fold type I ω-transaminase from Pseudomonas jessenii. A large number of surface-located point mutations and mutations predicted to stabilize the subunit interface were examined. Experimental screening revealed that 10 surface mutations out of 172 tested were indeed stabilizing (6% success), whereas testing 34 interface mutations gave 19 hits (56% success). Both the extent of stabilization and the spatial distribution of stabilizing mutations showed that the subunit interface was critical for stability. After mutations were combined, 2 very stable variants with 4 and 6 mutations were obtained, which in comparison to wild type (T_m ^app = 62 °C) displayed T_m ^app values of 80 and 85 °C, respectively. These two variants were also 5-fold more active at their optimum temperatures and tolerated high concentrations of isopropylamine and cosolvents. This allowed conversion of 100 mM acetophenone to (S)-1-phenylethylamine (>99% enantiomeric excess) with high yield (92%, in comparison to 24% with the wild-type transaminase). Crystal structures mostly confirmed the expected structural changes and revealed that the most stabilizing mutation, I154V, featured a rarely described stabilization mechanism: namely, removal of steric strain. The results show that computational interface redesign can be a rapid and powerful strategy for transaminase stabilization.

Original language	English
Pages (from-to)	2915-2928
Number of pages	14
Journal	ACS Catalysis
Volume	10
Issue number	5
DOIs	https://doi.org/10.1021/acscatal.9b05223
State	Published - Mar 6 2020
Externally published	Yes

Funding

Q.M. thanks the China Scholarship Council for a Ph.D. fellowship. Part of this project has received funding from the European Union's Horizon 2020 Programme (Marie Curie Actions-ITN ES-Cat) under GA No. 722610, which supported N.C. C.M.P. was supported by Erasmus Mundus, Eurotango II. The work of M.O., E.L., and H.J.W. was supported by the Dutch Ministry of Economic Affairs through BE-Basic grant FS02.005. We thank the staff of the ESRF at Grenoble for excellent onsite support and beam time allocation. Q.M. thanks the China Scholarship Council for a Ph.D. fellowship. Part of this project has received funding from the European Union’s Horizon 2020 Programme (Marie Curie Actions-ITN ES-Cat) under GA No. 722610, which supported N.C. C.M.P. was supported by Erasmus Mundus, Eurotango II. The work of M.O., E.L., and H.J.W. was supported by the Dutch Ministry of Economic Affairs through BE-Basic, grant FS02.005. We thank the staff of the ESRF at Grenoble for excellent onsite support and beam time allocation.

Keywords

biocatalysis
computational design
protein engineering
subunit interface
thermostability
transaminase

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10.1021/acscatal.9b05223

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title = "Robust ω-Transaminases by Computational Stabilization of the Subunit Interface",

abstract = "Transaminases are attractive catalysts for the production of enantiopure amines. However, the poor stability of these enzymes often limits their application in biocatalysis. Here, we used a framework for enzyme stability engineering by computational library design (FRESCO) to stabilize the homodimeric PLP fold type I ω-transaminase from Pseudomonas jessenii. A large number of surface-located point mutations and mutations predicted to stabilize the subunit interface were examined. Experimental screening revealed that 10 surface mutations out of 172 tested were indeed stabilizing (6% success), whereas testing 34 interface mutations gave 19 hits (56% success). Both the extent of stabilization and the spatial distribution of stabilizing mutations showed that the subunit interface was critical for stability. After mutations were combined, 2 very stable variants with 4 and 6 mutations were obtained, which in comparison to wild type (Tm app = 62 °C) displayed Tm app values of 80 and 85 °C, respectively. These two variants were also 5-fold more active at their optimum temperatures and tolerated high concentrations of isopropylamine and cosolvents. This allowed conversion of 100 mM acetophenone to (S)-1-phenylethylamine (>99% enantiomeric excess) with high yield (92%, in comparison to 24% with the wild-type transaminase). Crystal structures mostly confirmed the expected structural changes and revealed that the most stabilizing mutation, I154V, featured a rarely described stabilization mechanism: namely, removal of steric strain. The results show that computational interface redesign can be a rapid and powerful strategy for transaminase stabilization.",

keywords = "biocatalysis, computational design, protein engineering, subunit interface, thermostability, transaminase",

author = "Qinglong Meng and Nikolas Capra and Palacio, {Cyntia M.} and Elisa Lanfranchi and Marleen Otzen and {Van Schie}, {Luc Z.} and Rozeboom, {Henri{\"e}tte J.} and Thunnissen, {Andy Mark W.H.} and Wijma, {Hein J.} and Janssen, {Dick B.}",

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doi = "10.1021/acscatal.9b05223",

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AU - Meng, Qinglong

AU - Capra, Nikolas

AU - Palacio, Cyntia M.

AU - Lanfranchi, Elisa

AU - Otzen, Marleen

AU - Van Schie, Luc Z.

AU - Rozeboom, Henriëtte J.

AU - Thunnissen, Andy Mark W.H.

AU - Wijma, Hein J.

AU - Janssen, Dick B.

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N2 - Transaminases are attractive catalysts for the production of enantiopure amines. However, the poor stability of these enzymes often limits their application in biocatalysis. Here, we used a framework for enzyme stability engineering by computational library design (FRESCO) to stabilize the homodimeric PLP fold type I ω-transaminase from Pseudomonas jessenii. A large number of surface-located point mutations and mutations predicted to stabilize the subunit interface were examined. Experimental screening revealed that 10 surface mutations out of 172 tested were indeed stabilizing (6% success), whereas testing 34 interface mutations gave 19 hits (56% success). Both the extent of stabilization and the spatial distribution of stabilizing mutations showed that the subunit interface was critical for stability. After mutations were combined, 2 very stable variants with 4 and 6 mutations were obtained, which in comparison to wild type (Tm app = 62 °C) displayed Tm app values of 80 and 85 °C, respectively. These two variants were also 5-fold more active at their optimum temperatures and tolerated high concentrations of isopropylamine and cosolvents. This allowed conversion of 100 mM acetophenone to (S)-1-phenylethylamine (>99% enantiomeric excess) with high yield (92%, in comparison to 24% with the wild-type transaminase). Crystal structures mostly confirmed the expected structural changes and revealed that the most stabilizing mutation, I154V, featured a rarely described stabilization mechanism: namely, removal of steric strain. The results show that computational interface redesign can be a rapid and powerful strategy for transaminase stabilization.

AB - Transaminases are attractive catalysts for the production of enantiopure amines. However, the poor stability of these enzymes often limits their application in biocatalysis. Here, we used a framework for enzyme stability engineering by computational library design (FRESCO) to stabilize the homodimeric PLP fold type I ω-transaminase from Pseudomonas jessenii. A large number of surface-located point mutations and mutations predicted to stabilize the subunit interface were examined. Experimental screening revealed that 10 surface mutations out of 172 tested were indeed stabilizing (6% success), whereas testing 34 interface mutations gave 19 hits (56% success). Both the extent of stabilization and the spatial distribution of stabilizing mutations showed that the subunit interface was critical for stability. After mutations were combined, 2 very stable variants with 4 and 6 mutations were obtained, which in comparison to wild type (Tm app = 62 °C) displayed Tm app values of 80 and 85 °C, respectively. These two variants were also 5-fold more active at their optimum temperatures and tolerated high concentrations of isopropylamine and cosolvents. This allowed conversion of 100 mM acetophenone to (S)-1-phenylethylamine (>99% enantiomeric excess) with high yield (92%, in comparison to 24% with the wild-type transaminase). Crystal structures mostly confirmed the expected structural changes and revealed that the most stabilizing mutation, I154V, featured a rarely described stabilization mechanism: namely, removal of steric strain. The results show that computational interface redesign can be a rapid and powerful strategy for transaminase stabilization.

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KW - computational design

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EP - 2928

JO - ACS Catalysis

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ER -

Robust ω-Transaminases by Computational Stabilization of the Subunit Interface

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